Pin cadence for high-speed connectors

ABSTRACT

A connector includes pins having a pinout including a functional designation cadence. The functional designation cadence includes a first ground pin, a first signal pin, a no-connect pin, a second signal pin, and a second ground pin, where the first signal pin is positioned between the first ground pin and the no-connect pin, the no-connect pin is positioned between the first and second signal pins, and the second signal pin is positioned between the no-connect pin and the second ground pin. Alternately, the functional designation cadence includes a first ground pin, a first signal pin, a third ground pin, a second signal pin, and a second ground pin, where the first signal pin is positioned between the first and third ground pins, the third ground pin is positioned between the first and second signal pins, and the second signal pin is positioned between the third and second ground pins.

CROSS-REFERENCE TO RELATED APPLICATIONS

This patent application claims the benefit of and priority to U.S.Provisional Application No. 61/732,886, filed Dec. 3, 2012, to U.S.Provisional Application No. 61/732,861, filed Dec. 3, 2012, and to U.S.Provisional Application No. 61/732,868, filed Dec. 3, 2012. Theforegoing provisional applications are incorporated herein by reference.

FIELD

The embodiments discussed herein relate to connectors with pins. Moreparticularly, some example embodiments relate to pins in a connectorthat have a repeating functional designation cadence.

BACKGROUND

Optical cables can be implemented in applications in which data iscommunicated between host systems. For example, a first host system maytransmit data to a second host system via the optical cable. Opticalconnectors may be attached to the ends of the optical cable to provide amechanical coupling between the ends of the optical cable and thecorresponding host systems. The optical connectors generally include aset of pins that interface with complementary pins or receivers in areceiver of the host system.

Dimensions of optical connectors are decreasing in size while at thesame time the amount of data communicated through the optical connectorsis increasing. In some designs, the reduction in size dictates relativepositions of components included in the optical connectors. The relativepositions may reduce the ability to reliably transfer data through theoptical connectors.

The subject matter claimed herein is not limited to embodiments thatsolve any disadvantages or that operate only in environments such asthose described above. Rather, this background is only provided toillustrate one exemplary technology area where some embodimentsdescribed herein may be practiced.

SUMMARY

Embodiments relate to connectors with pins. More particularly, someexample embodiments relate to pins in a connector that have a repeatingfunctional designation cadence.

This Summary introduces a selection of concepts in a simplified formthat are further described below in the Detailed Description. ThisSummary is not intended to identify key features or essentialcharacteristics of the claimed subject matter, nor is it intended to beused as an aid in determining the scope of the claimed subject matter.

In an example embodiment, a connector includes multiple pins having apinout including at least one functional designation cadence. Thefunctional designation cadence may include a first ground pin, a firstsignal pin, a no-connect pin, a second signal pin, and a second groundpin, where the first signal pin is positioned between the first groundpin and the no-connect pin, the no-connect pin is positioned between thefirst signal pin and the second signal pin, and the second signal pin ispositioned between the no-connect pin and the second ground pin.Alternately, the functional designation cadence may include a firstground pin, a first signal pin, a third ground pin, a second signal pin,and a second ground pin, where the first signal pin is positionedbetween the first ground pin and the third ground pin, the third groundpin is positioned between the first signal pin and the second signalpin, and the second signal pin is positioned between the third groundpin and the second ground pin.

Additional features and advantages will be set forth in the descriptionwhich follows, and in part will be obvious from the description, or maybe learned by the practice of the embodiments. The features andadvantages of the embodiments will be realized and obtained by means ofthe instruments and combinations particularly pointed out in the claims.These and other features will become more fully apparent from thefollowing description and claims, or may be learned by the practice ofthe embodiments as set forth hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

To further clarify the above and other advantages and features of thepresent invention, a more particular description of the invention willbe rendered by reference to specific embodiments thereof which areillustrated in the appended drawings. It is appreciated that thesedrawings depict only some embodiments of the invention and are thereforenot to be considered limiting of its scope. The invention will bedescribed and explained with additional specificity and detail throughthe use of the accompanying drawings in which:

FIGS. 1A and 1B illustrate an optoelectronic connector (hereinafter“connector”) in which some embodiments disclosed herein may beimplemented;

FIGS. 2A and 2B illustrate example pinouts that may be implemented inthe connector of FIGS. 1A and 1B;

FIGS. 3A and 3B illustrate example pins that may be implemented in theconnector of FIGS. 1A and 1B; and

FIG. 4 illustrates an example forty-one pin host connector coupled tothe connector of FIGS. 1A and 1B.

DETAILED DESCRIPTION OF SOME EXAMPLE EMBODIMENTS

Some example embodiments described herein include a connector withmultiple pins. In a particular embodiment, the pins may include fort-onepins. More generally, the pins include a repeating functionaldesignation cadence. The functional designation cadence may include afirst ground pin, a first signal pin, a third ground pin, a secondsignal pin, and a second ground pin. By separating the first signal pinand the second signal pin with the third ground pin, the impedancebetween the first signal pin and the second signal pin may be maintainedand the signal integrity may be improved relative to at least some otherdesigns. The pins of the connector may additionally include two powerpins, which have a shorter length than the other pins. Each of the pinsmay define two openings configured to reduce parasitic capacitanceimposed by the pins.

Reference will now be made to the figures wherein like structures willbe provided with like reference designations. The drawings arediagrammatic and schematic representations of exemplary embodiments and,accordingly, are not limiting of the scope of the claimed subjectmatter, nor are the drawings necessarily drawn to scale.

FIGS. 1A and 1B illustrates an optoelectronic connector 100 (hereinafter“connector 100”) in which some embodiments disclosed herein may beimplemented. FIG. 1A depicts a perspective view of the connector 100.The connector 100 may include a connector housing 114, anelectromagnetic radiation shield 112 (hereinafter “EMR shield 112”), andmultiple pins 102 at least partially surrounded by the EMR shield 112.FIG. 1B depicts the connector 100 with the connector housing 114 and theEMR shield 112 removed to make visible some internal components (e.g.110 and 108) of the connector 100. As illustrated in FIGS. 1A and 1B,the connector 100 may be coupled to an end of an optical cable thatincludes a set of one or more optical fibers 104.

Generally, the connector 100 is configured to receive, convert, andcommunicate high-speed data (e.g. 10 gigabits/second or higher perchannel) between the pins 102 and the optical fibers 104. The pins 102may be composed of an electrically conductive material and may beconfigured to receive data in the form of electrical signals from a hostsystem (not shown) to which the connector 100 may be coupled. The pins102 may communicate the electrical signals to a printed circuit board(PCB) 108 (FIG. 1B) of the connector 100. The PCB 108 generally includesone or more contacts (not shown) and one or more electrical traces (notshown) that electrically couple the pins 102 to optical components (notshown) positioned within and/or under a lens assembly 110 of theconnector 100. The optical components may be configured to convert theelectrical signals to the optical domain and to transmit the data, nowin the form of optical signals representative of the electrical signals,into one or more of the optical fibers 104. In this described function(e.g., receiving electrical signals from the host system and convertingto optical signals) of the connector 100, the optical components mayinclude an optical transmitter, such as a vertical-cavitysurface-emitting laser (VCSEL). Alternately or additionally, theconnector 100 may include at least one laser driver configured to driveat least one corresponding optical transmitter to emit an optical signalrepresentative of a corresponding one of the electrical signals receivedfrom the host system.

Additionally, the connector 100 can receive data in the form of opticalsignals that are transmitted along the optical fibers 104 from an end ofthe optical fibers 104 that is opposite the end of the optical fibers104 in FIGS. 1A and 1B. The optical signals may be communicated to oneor more optical components positioned within and/or under the lensassembly 110. The optical components may be configured to convert theoptical signals to electrical signals that are communicated along one ormore of the electrical traces to one or more of the contacts on the PCB108 and then to one or more of the pins 102. In this described function(e.g., receiving optical signals and converting to electrical signals),the optical components may include at least one optical receiver such asa PIN photodiode or another optical component capable of receiving anoptical signal and generating a representative electrical signaltherefrom.

The EMR shield 112 may surround the pins 102 such that electromagneticradiation (EMR) that may be generated through the communication ofhigh-speed data by the connector 100 may be contained within theconnector 100. For example, the EMR shield 112 may absorb or receive EMRand subsequently ground the EMR such that any electromagneticinterference (EMI) may be attenuated and/or otherwise at least partiallyprevented from escaping the connector 100. Accordingly, the EMR shield112 may at least partially reduce EMI exiting the connector 100 into asurrounding system, such as a host system. In some embodiments, the EMRshield 112 may be composed of a metal for efficient conduction of theEMR.

In the depicted embodiment, the optical fibers 104 are substantiallyoriented parallel to the pins 102. However, this is not meant to belimiting. In some embodiments, the optical fibers 104 are orientednormal to the pins 102. In embodiments in which the optical fibers 104are oriented normal to the pins 102, the electrical trace on the PCB 108may have different designs but otherwise equivalent function.

The connector 100 is configured to be received by and mechanically andcommunicatively coupled to a host connector (not shown). The hostconnector may be integrated within a host system such as a television, amonitor, a media box, or another suitable computing device. The hostconnector may be configured to correspond and be complementary to theconnector 100. Specifically, in the following example functionaldesignation cadence of the pins 102, a host connector may include pinswith a complementary functional designation cadence such that data maybe communicated from the host system to the connector 100 and/or fromthe connector 100 to the host system via the host connector.

In the connector 100, the pins 102 may be arranged according to apinout. Generally, the pinout refers to a functional description of eachof the pins 102 and/or the corresponding contacts on the PCB 108 and/ora host system to which the pins 102 are electrically coupled. Severaladvantages may be obtained by using a particular pinout. For example,during the communication of high-speed data, impedance between adjacentsignal pins may drop when the signal pins are positioned within aminimum distance of each other. That is, the signal pins may be tooclose together, which may create capacitance between the signal pins anda corresponding loss of or reduction in impedance. The loss of orreduction in impedance may prevent high-speed data from beingcommunicated using the signal pins and/or may degrade high-speed datacommunicated using the signal pins. Accordingly, some embodimentsdescribed herein may separate the signal pins to maintain a desiredimpedance. However, a difficulty may arise during a manufacturingprocess of the connector 100 with inconsistent separation distancesbetween pins 102. Alternately or additionally, a pitch between the pins102 may be constant due to a paddle used in automated manufacturingprocesses. Thus, it may present a cost advantage to maintain a constantpitch between the pins 102.

FIGS. 2A and 2B illustrate example pinouts 200A and 200B that may beimplemented in the connector 100 of FIGS. 1A and 1B for the pins 102.Generally, the pinouts 200A and 200B may enable separation of signalpins while reducing manufacturing costs. FIGS. 2A and 2B describe thepinouts 200A and 200B with reference to a set of contacts 202A-202J(generally contact 202 or contacts 202) that may be formed on therespective PCBs 108 described above with reference to FIGS. 1A and 1B.Each of the contacts 202 may be electrically coupled to a pin such asone of the pins 102 of FIGS. 1A and 1B.

The pinouts 200A and 200B respectively include functional designationcadences 204A and 204B for a first subset of the contacts 202A-202E. Thefunctional designation cadences 204A and 204B are generally repeated fora second subset of the contacts 202F-202J, as well as for subsequentsubsets of contacts 202, if any.

With specific reference to FIG. 2A, the functional designation cadence204A may include a first ground contact which is the function ofcontacts 202A and 202F, a first signal contact which is the function ofcontacts 202B and 202G, a no-connect which is the function of thecontacts 202C and 202H, a second signal contact which is the function ofthe contacts 202D and 202I, and a second ground contact which is thefunction of the contacts 202E and 202J. Each of the ground contacts(e.g., the first ground contact and the second ground contact) isdesignated as “GND” in FIG. 2A. Each of the signal contacts (e.g., thefirst signal contacts and the second signal contacts) is designated as“SIG” in FIG. 2A. Each of the no-connects is designated in FIG. 2A as“NC”. Alternately or additionally, the first signal contact and thesecond signal contact within each subset of contacts may be adifferential signal pair.

In some embodiments, a pin (such as the pins 102 of FIGS. 1A and 1B) iselectrically coupled to each of the contacts 202. Accordingly, in theseand other embodiments, the functional designation cadence 204A mayinclude a ground pin, a first signal pin, a no-connect pin, a secondsignal pin, and a second ground pin arranged in sequence. Alternatively,the no-connects (e.g., contacts 202C and 202H) may not be coupled to apin. Accordingly, in these and other embodiments, the functionaldesignation cadence 204 may include a first ground pin, a first signalpin, a second signal pin, and a second ground pin arranged in sequence.

Alternatively, with specific reference to FIG. 2B, the functionaldesignation cadence 204B may include a first ground contact which is thefunction of contacts 202A and 202F, a first signal contact which is thefunction of contacts 202B and 202G, a third ground contact which is thefunction of the contacts 202C and 202H, a second signal contact which isthe function of the contacts 202D and 202I, and a second ground contactwhich is the function of the contacts 202E and 202J. Each of the groundcontacts (e.g., the first ground contact, the second ground contact, andthe third ground contact) is designated as “GND” in FIG. 2B. Each of thesignal contacts (e.g., the first signal contact and the second signalcontacts) is designated as “SIG” in FIG. 2B. Alternately oradditionally, the first signal contact and the second signal contactwithin each subset of contacts may be a differential signal pair.

In some embodiments, a pin (such as the pins 102 of FIGS. 1A and 1B) iselectrically coupled to each of the contacts 202. Accordingly, in theseand other embodiments, the functional designation cadence 204B mayinclude a ground pin, a first signal pin, a third ground pin, a secondsignal pin, and a second ground pin arranged in sequence. Alternatively,the third ground contact (e.g., contacts 202C and 202H) may not becoupled to a pin. Accordingly, in these and other embodiments, thefunctional designation cadence 204 may include a first ground pin, afirst signal pin, a second signal pin, and a second ground pin arrangedin sequence.

Referring again to both FIGS. 2A and 2B, the PCB 108 includes multipleelectrical traces 206. The electrical traces 206 electrically coupleoptical components 214 to the signal contacts 202B, 202D, 202G, and 202Isuch that electrical signals may be communicated along the electricaltraces 206. Although not shown, one or more circuits may be positionedbetween each optical component 214 and corresponding signal contact202B, 202D, 202G, and 202I, such as a laser driver when thecorresponding optical component 214 includes an optical transmitter or apost-amplifier (PA) when the corresponding optical component 214includes an optical receiver. As mentioned above, the optical components214 may be positioned within and/or under the lens assembly 110described with respect to FIGS. 1A and 1B.

Included on the electrical traces 206 may be a coupling capacitor 212and/or a loop 210. The coupling capacitors 212 and the loops 210 maymatch lengths or establish capacitance, impedance, or inductance of theelectrical traces 206. The PCB 108 may also include one or more vias208. The vias 208 may couple the first and the second ground contacts202A, 202E, 202F, and 202J to an electrical ground within the PCB 108.In the embodiment depicted in FIG. 2A, the “no connect” contact is notconnected to the PCB 108 and accordingly, no electrical trace 206 or via208 is coupled thereto. In contrast, in the embodiment of FIG. 2B, aground coupling 216 connects the third ground contact (e.g., contacts202C and 202H) to the electrical ground. In some embodiments, the groundcoupling 216 may include a via substantially similar to the vias 208,for instance. As illustrated in FIGS. 2A and 2B, the PCB 108 may repeatthe electrical traces 206, the coupling capacitors 212, the loop 210,the vias 210, and the ground coupling 216 for each of the functionaldesignation cadences 204A and 204B.

Separating the first signal contacts 202B and 202G from the secondsignal contacts 202D and 202I with the no-connect contacts or with thethird ground contacts 202C and 202H may maintain an impedance betweenthe first signal contacts 202B and 202G and the second signal contacts202D and 202I. For example, the impedance may be maintained at 100 Ohmsor other suitable impedance. Alternately or additionally, grounding theground contacts 202C and 202H positioned between the signal contacts202B, 202D, 202G, 202I may improve signal integrity of data communicatedover the signal contacts 202B, 202D, 202G, and 202I.

In some embodiments, the no-connect or the third ground contacts 202Cand 202H may have some functional use. For example, a pin coupled to theno-connect or the third ground contacts 202C and 202H may be used duringactive alignment. During active alignment, the no-connect or the thirdground contacts 202C and 202H may act as a direct current output from anintegrated circuit included in a connector, such as the connector 100 ofFIGS. 1A and 1B. Alternately or additionally, including the pin coupledto the no-connect or the third ground contacts 202C and 202H mayslightly (e.g., at least partially) couple the first signal contacts202B and 202G to the second signal contacts 202D and 202I. Thus, somebenefits to the communication of data may be derived by having the pincoupled to the no-connect or the third ground contacts 202C and 202Hwhich is positioned between the pins coupled to the first signalcontacts 202B and 202G and the second signal contacts 202D and 202I.

FIGS. 3A and 3B illustrate some additional details of an examplearrangement of the pins 102 that may be implemented in the connector 100of FIGS. 1A and 1B. FIG. 3A depicts a top view of the pins 102 and FIG.3B depicts a side view of the pins 102. Generally, the pins 102 arecoupled to the PCB 108 described above at a set of contacts 304. Thecontacts 304 are substantially similar to and may correspond to thecontacts 202 described with reference to FIGS. 2A and 2B. For example,the contacts 304 may be arranged and configured according to thefunctional designation cadence 204A or 204B of FIGS. 2A and 2B.

The pins 102 generally include and/or may be arranged according to oneof the pinouts 200A and 200B described with respect to FIGS. 2A and 2B.The pins 102 may additionally include two power pins 306. For example,the embodiment shown in FIGS. 3A and 3B includes forty-one pins 102 thatmay be numbered one through forty-one. In the example embodimentsincluding forty-one pins, the functional designation cadence 204B or204A respectively including a first ground pin, a first signal pin, athird ground pin, a second signal pin, and a second ground pin orincluding a first ground pin, a first signal pin, a no contact pin, asecond signal pin, and a second ground pin may be repeated multipletimes. For example, the functional designation cadence may be repeatedsix times.

Referring back to FIGS. 3A and 3B, the pins 102 may have two or morelengths 308 and 310. In this and other embodiments, the power pins 306have a first length 310 that is less than a second length 308 of theremaining pins 102. The relatively shorter first length 310 of the powerpins 306 may ensure that when the connector 100 is introduced into acorresponding host connector, the power pins 306 do not make contactwith corresponding pins of the host connector until after the other pins102 (including the ground pins). This may ensure that ground pins aregrounded prior to providing power, which may reduce the occurrence ofreversed biased diodes, etc.

Additionally, with specific reference to FIG. 3A, the pins 102 and 306may be separated by a pitch 312. The pitch 312 generally refers to thecenter-to-center spacing or distance between adjacent ones of the pins102 and 306. In this and other embodiments, the pitch 312 is constant.For example, the pins 102 and 306 may be spaced at a pitch of 0.5millimeters (mm). By keeping the pitch 312 constant, a connectorincluding the PCB 108 and the pins 102 may be more easily manufactured.

In an alternative embodiment, the pitch 312 may be constant (e.g. 0.5mm) but the pins 102 may not be coupled to no-connect contacts or thethird ground pins. In these alternative embodiments, the first signalpin, which is positioned between the first ground pin and the secondsignal pin, may be separated from the first ground pin by the pitch andmay be separated from the second signal pin by two times the pitch. Inaddition, the second signal pin is positioned between the first signalpin and the second ground pin, the second signal pin being separatedfrom the second ground pin by the pitch.

With specific reference to FIG. 3B, the pins 102 may define one or moreopenings 314. Because capacitance varies based on surface area, definingthe openings 314 may result in a reduction in parasitic capacitanceimposed by the pins 102. In the depicted embodiment, the openings 314are substantially oval in shape and there are two openings 314 definedin each of the pins 102. However, this is not meant to be limiting. Insome embodiments, the pins 102 may include one or three or more openings314 that may have any suitable shape.

FIG. 4 illustrates an example forty-one pin host connector 400 coupledto the connector 100 of FIGS. 1A and 1B. Generally, the connector 100 isreceived within a corresponding structure of the host connector 400 suchthat the pins (not shown) of the connector 100 contact a correspondingstructure included in the host connector 400. The host connector 400includes a host PCB 402 which may be similar in at least some respectsto the PCB 108 of the connector 100. Specifically, both of the PCB 108and the host PCB 402 may include electrical traces as described withreference to FIGS. 2A and 2B. Additionally, the host connector 400includes a complementary pinout to that of the connector 100.

In this and other embodiments, the pinout of the connector 100 and thehost connector 400 may include a functional designation cadence 404. Thefunctional designation cadence 404 may be substantially equivalent toeither of the functional designation cadences 204A or 204B describedwith reference to FIGS. 2A and 2B. Specifically, the functionaldesignation cadence 404 may include a first ground pin, a first signalpin, a third ground pin, a second signal pin, and a second groundpin—similar to the functional designation cadence 204B of FIG. 2B—or thefunctional designation cadence 404 may include a first ground pin, afirst signal pin, a no-connect pin, a second signal pin, and a secondground pin—similar to the functional designation cadence 204A of FIG.2A. In the connector 100, the functional designation cadence 404 may berepeated six times. Likewise, in the pinout of the host connector 400,the functional designation cadence 404 may be repeated six times.Additionally, the pinout of the connector 100 and the host connector 400includes two power pins 406. The power pins 406 are located in thecenter two pins of the pinout. Whereas the host connector 400 mayinclude 41 pins and the connector 100 may include 41 pins, and whereas30 of the pins of each may be used in the six repeating subsets of thefunctional design cadence 404, and whereas 2 of the pins of each may beimplemented as the power pins 406, 9 pins may remain for each. The 9remaining pins may be used for a two-wire interface between the hostconnector 400 and the connector 100 and/or for other purposes.

The depicted embodiment of FIG. 4 may be implemented in a system drivingsix optical components. For example, each of the functional designationcadences 404 may be configured to communicate high-speed differentialelectrical signals to or from a corresponding one of the six opticalcomponents.

Embodiments described herein may be implemented in active cable devicesthat include an optical cable with one or more optical fibers and anoptoelectronic connector at each end of the optical cable. The opticalcable with one or more optical fibers may include or correspond to theoptical cable with optical fibers 104 illustrated in and described withrespect to FIGS. 1A and 1B. The optoelectronic connectors, one at eachend, may include or correspond to the connector 100 described herein.

The present invention may be embodied in other specific forms. Thedescribed embodiments are to be considered in all respects only asillustrative and not restrictive. The scope of the invention is,therefore, indicated by the appended claims rather than by the foregoingdescription. All changes which come within the meaning and range ofequivalency of the claims are to be embraced within their scope.

1. A connector comprising: a plurality of pins having a pinout includingat least one functional designation cadence including: a first groundpin, a first signal pin, a no-connect pin, a second signal pin, and asecond ground pin, wherein the first signal pin is positioned betweenthe first ground pin and the no-connect pin, the no-connect pin ispositioned between the first signal pin and the second signal pin, andthe second signal pin is positioned between the no-connect pin and thesecond ground pin; or a first ground pin, a first signal pin, a thirdground pin, a second signal pin, and a second ground pin, wherein thefirst signal pin is positioned between the first ground pin and thethird ground pin, the third ground pin is positioned between the firstsignal pin and the second signal pin, and the second signal pin ispositioned between the third ground pin and the second ground pin. 2.The connector of claim 1, wherein the functional designation cadence isrepeated at least two times in the pinout.
 3. The connector of claim 1,wherein the first signal pin and the second signal are configured tocarry a differential electrical signal having a data rate of about 10gigabits/second or higher.
 4. The connector of claim 1, wherein theno-connect pin or the third ground pin is used during active alignmentas a direct current output from an integrated circuit included in theconnector.
 5. The connector of claim 1, further comprising six opticalcomponents, wherein the plurality of pins comprises forty-one pins, theforty-one pins including the functional designation cadence repeated sixtimes for six corresponding subsets of pins, each of the sixcorresponding subsets of pins configured to communicate a high-speeddifferential electrical signal to or from a corresponding one of the sixoptical components.
 6. The connector of claim 1, wherein at least one ofthe plurality of pins includes an opening formed therein.
 7. Theconnector of claim 1, wherein the plurality of pins comprises at leastone power pin having a length that is less than a length of other pinsof the plurality of pins.
 8. The connector of claim 1, wherein animpedance between the first signal pin and the second signal pin isabout 100 ohms.
 9. The connector of claim 1, wherein the plurality ofpins have a constant pitch of about 0.5 millimeters.
 10. The connectorof claim 1, further comprising a metallic electromagnetic radiationshield that at least partially surrounds the plurality of pins.
 11. Theconnector of claim 1, further comprising a printed circuit board thatincludes a plurality of contacts to which the plurality of pins areelectrically coupled.
 12. The connector of claim 11, wherein the printedcircuit board comprises a first via coupling the first ground pin to anelectrical ground and a second via coupling the second ground pin to theelectrical ground.
 13. The connector of claim 12, wherein the printedcircuit board further comprises a first signal trace that couples thefirst signal pin to a first optical component and a second signal tracethat couples the second signal pin to a second optical component.
 14. Aconnector comprising: a plurality of pins having a pinout including atleast one functional designation cadence including a first ground pin, afirst signal pin, a second signal pin, and a second ground pin, wherein:the first signal pin is positioned between the first ground pin and thesecond signal pin; the first signal pin is separated from the firstground pin by a pitch; the first signal pin is separated from the secondsignal pin by two times the pitch; the second signal pin is positionedbetween the first signal pin and the second ground pin; and the secondsignal pin is separated from the second ground pin by the pitch; aprinted circuit board (PCB) including a plurality of contactselectrically coupled to the plurality of pins and having a PCB contactpinout including a PCB contact functional designation cadencecorresponding to the at least one functional designation cadence,wherein the PCB contact functional designation cadence includes a firstground contact, a first signal contact, a second signal contact, and asecond ground contact arranged in sequence according to the functionaldesignation cadence; and a metallic electromagnetic radiation shieldthat at least partially surrounds the plurality of pins.
 15. An activecable device comprising: an optical cable having opposing first andsecond ends and including an optical fiber extending from the first endto the second end; and an optoelectronic connector coupled to the firstend of the optical cable, wherein the optoelectronic connectorcomprises: a connector housing; a printed circuit board (PCB) positionedwithin the connector housing; an optical component coupled to the PCB,wherein the optical component is optically coupled to a first end of theoptical fiber so as to emit light into or receive light from the opticalfiber; a plurality of pins having a pinout including at least onefunctional designation cadence including a first ground pin, a firstsignal pin, a second signal pin, and a second ground pin, wherein: thefirst ground pin, the first signal pin, the second signal pin, and thesecond ground pin are arranged in sequence; the PCB includes a pluralityof contacts arranged in sequence according to the functional designationcadence; the plurality of contacts of the PCB include a first groundcontact coupled to the first ground pin, a first signal contact coupledto the first signal pin, a second signal contact coupled to the secondsignal pin, and a second ground contact coupled to the second groundpin; and the PCB includes a plurality of traces, including a first tracethat electrically couples the first ground contact to the opticalcomponent and a second trace that electrically couples the second groundcontact to the optical component.
 16. The active cable device of claim15, wherein the at least one functional designation cadence furtherincludes a no-connect pin or a third ground pin positioned between thefirst signal pin and the second signal pin.
 17. The active cable deviceof claim 15, wherein each of the plurality of pins defines at least twoopenings.
 18. The active cable device of claim 15, wherein: theplurality of pins include a set of non-power pins and a set of powerpins; each pin in the set of non-power pins extends a first distancefrom the PCB; and each pin in the set of power pins extends a seconddistance from the PCB that is less than the first distance.
 19. Theactive cable device of claim 15, further comprising a lens assemblycoupled to the PCB, wherein the optical component is positioned withinand/or under the lens assembly.
 20. The active cable device of claim 19,further comprising an electromagnetic radiation shield that at leastpartially surrounds the plurality of pins, wherein the electromagneticradiation shield and the connector housing cooperate to enclose andprotect the PCB, the optical component, the plurality of pins, and thelens assembly.